JPH0455761B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to an edging roll used in manufacturing a section having a flange, such as an H-section steel.

[Prior Art] A universal rolling method is generally used to roll a section having a flange (hereinafter abbreviated as H-section steel, etc.), such as H-section steel. FIG. 9 is a diagram showing an example of the universal rolling method. 1 is a breakdown mill, for example, a steel billet with a cross section of 1-1,
It is rolled into 1-2 rough shaped steel pieces with a cross section similar to H-beam steel or the like. 2 is a universal rolling mill that rolls down the web portion of the rough shaped steel billet 1-2 with two horizontal rolls 2a, upper and lower, and simultaneously rolls down the flange portion with two vertical rolls 2b and horizontal rolls 2a on the left and right. do. This rolling is repeated several times. 2-1 is the cross-sectional shape of the rolled material at the initial rolling pass, and 2-2 is the cross-sectional shape of the rolled material after several rolling passes.

Reference numeral 3 denotes an etching rolling mill, which is installed in series with the universal rolling mill 2, and rolls down the flange portion of the rolled material in the flange width direction with two upper and lower etching rolls 3a, forging the end of the flange, and rolling the flange. Adjust the width dimension. This etching rolling is repeated several times, for example alternately, between each pass of universal rolling.

That is, a rolled material with a shape of 2-1 in universal rolling is edge-rolled as shown in 3-1, and a rolled material with a shape of 2-2 in universal rolling is set by widening the interval between the upper and lower etching rolls, and -Edge rolling as in step 2.

However, in this edging rolling method, for example, 3-
When the rolled material in step 2 is edge-rolled, a clearance S occurs between the edge roll and the web of the rolled material, so the amount of reduction in the edging becomes inaccurate, and the guidance of the rolled material by the edge roll also This resulted in inaccurate movement due to side-to-side deviation, leading to dimensional defects and shape defects in H-beams, etc.

In Fig. 9, 4 is the finishing universal rolling machine.
The shape and dimensions of the rolled material 3-2 are controlled by two horizontal rolls 4a (upper and lower) and two vertical rolls 4b (left and right).
-2, and make products such as H-shaped steel.

FIG. 10 is a diagram showing an example of an inconvenient problem that occurs in the conventional edging rolling method. Figure A is a diagram showing an example in which there is a clearance between the edge roll and the web of the rolled material, the guidance and reduction of the rolled material by the edge roll is inappropriate, and the shape of the rolled material is distorted. In addition, Figure B-1 shows an example where only the upper roll hits the web of the rolled material and pushes the web down.As shown in the figure, when the web is pushed down, the web is pushed to a position offset from the center of the flange width. , even if this rolled material undergoes shape correction later,
As shown in Figure B-2, the web is not located at the center of the flange width (Web-Off-
Center) H-shaped steel. Figure C is an example of an edge roll that restrains the web and rolls down the flange end. The center deviation of H-section steel can be greatly improved by using the etching roll shown in Figure C. However, in the method shown in Fig. C, an edge roll with a different length of lc is required each time the flange width of the rolled material or the thickness of the web changes. In a rolling mill for shaped steel, many types of rolled materials with different flange widths and web thicknesses are rolled, so the method shown in Fig. C requires a large number of rolls to be kept on hand, and replacing the rolls is a hassle. Furthermore, in the method shown in Fig. C, the circumferential speed of the edge roll is different between the flange end and the web part of the rolled material, so it is difficult to adjust the rolling reduction to obtain an H-beam with good dimensions and shape. This causes surface scratches and uneven roll wear.

JP-A No. 62-077107 and Japanese Patent Application No. 61-205330 (JP-A No. 63-60008) can be commonly used for many types of rolled materials with different flange widths and web thicknesses, and can restrain the web. This is an etching roll that rolls down the flange end. These inventions restrain the web of the rolled material through the eccentric sleeve, but if the eccentricity of the eccentric sleeve is increased using these methods, the contact position between the rolled material and the roll will change to the flange as described later. Since the web shifts, good etching is difficult, and the rolled material is often accompanied by defects in biting and kicking out, vertical bending, and defects in cross-sectional shape and dimensions.

[Problems to be Solved by the Invention] The present invention can be used in common even when the flange width and web thickness of rolled materials change, and the web portion can always be restrained to allow the flange end to be rolled down. The object of the present invention is to disclose an edging roll for a profile having flanges, in which the web portion can be restrained at the most appropriate position.

[Means for Solving the Problems] FIG. 1 is a diagram showing an example of an edging roll of the present invention, in which A is a front view and B is a YY sectional view of A. That is, the present invention has the following features: (1) A flange rolling roll 8 having a flange rolling part 8a and a sleeve fitting part 8b is provided on the left and right sides of the main shaft 7 so as to rotate together with the main shaft 7, and the outside of the sleeve fitting part 8b is provided. Inner eccentric sleeve 5
The outer eccentric sleeve 6 is provided on the outside of the inner eccentric sleeve 5 so that it can be set by rotating on the outer circumference of the inner eccentric sleeve 5. An edging roll for a profile having a flange, characterized in that a web restraint roll 10 is provided on the outside of the sleeve 6 so as to be rotatable on the outer periphery of the outer eccentric sleeve 6. (2) A rolling roll 8 provided to rotate together with the main shaft 7 is a rolling roll provided to rotate together with the main shaft 7 and to be able to be set by sliding on the main shaft 7 in the axial direction. 8, the edging roll for a profile having a flange according to item (1) above. and (3) an inner sleeve positioning device that sets the inner eccentric sleeve 5 by rotating it on the outer periphery of 8b, and an outer sleeve positioning device that sets the outer eccentric sleeve 6 by rotating it on the outer periphery of 5. The edging roll for a profile having a flange according to (1) or (2) above, which is a sleeve positioning device equipped with a constant pressure holding mechanism. It is.

The present invention will be specifically explained below.

In FIG. 1, the flange rolling roll 8 is, for example, a key 9.
rotates with the main shaft 7 and applies rotational force in the direction around the shaft. Flange end 12 of rolled material 12
a is the flange rolling portion 8a of the flange rolling roll 8;
Roll with. When the flange width of the rolled material 12 changes,
The interval between the upper and lower main shafts 7 is changed and adjusted using a reduction adjustment device (not shown), and an appropriate amount of reduction is applied to the flange end of the rolled material 12. This rolling reduction adjustment device may be a normal roll rolling reduction adjustment device.

The flange rolling roll 8 can also be set to slide axially on the main shaft 7. When the web length of the rolled material 12 changes, the distance between the left and right rolling rolls 8 is changed and adjusted to match the web length of the rolled material 12 using a sliding adjustment device (not shown). This sliding adjustment device may be a known means such as a hydraulic cylinder system in which sliding is performed using a hydraulic branch pipe provided in the main shaft 7, or a screw system.

The flange rolling roll 8 has a sleeve fitting part 8.
b, and an inner eccentric sleeve 5 is provided on 8b, an outer eccentric sleeve 6 is placed on 5, and a web restraint roll 10 is fitted on 6 in order.

FIG. 2 is a diagram showing an example in which the setting positions are changed by rotating the flange rolling roll 8, the inner eccentric sleeve 5, and the outer eccentric sleeve 6.

In Figure A-1, the main shaft 7 is provided with a flange rolling roll 8 that rotates together with the main shaft. An inner eccentric sleeve 5 is arranged on the outside of the flange roll 8. 5 does not rotate with 8,
The settings are as shown. An outer eccentric sleeve 6 is arranged outside the inner eccentric sleeve 5.
6 is also set in the illustrated state and does not rotate with 8. A web restraint roll 10 is attached to the outside of 6 so as to be rotatable with respect to 6.

Figure B-1 is a cross-sectional view taken along line X-X in Figure A-1, and flanged rolling rolls 8 provided with the aforementioned 5, 6, and 10 are disposed on the left and right sides of the main shaft 7, respectively.

As already mentioned, the flange rolling roll 8 can be slid on the main shaft 7 in the axial direction to adjust and set the interval lW.

Figure C-1 is a diagram showing a cross section of the rolled material 12-1 during edge rolling with the inner eccentric sleeve 5 and the outer eccentric sleeve 6 set as shown in Figures A-1 and B-1. The flange end portion of the rolled material 12-1 is rolled and forged by a flange rolling roll 8, and the web portion is restrained by a web restraining roll 10. At this time, the rolled material 12-1 is moved by the force of rotation of the flange rolling roll 8, and the web restraint roll 10 is rotated around the outer periphery of the rolled material 12-1 by the movement of the rolled material 12-1.

When rolling a rolled material with a different flange width, for example 12-2, using this edging roll, the inner eccentric sleeve 5 is set by rotating around the flange rolling roll 8 to the position shown in Figure A-2. In addition, the outer eccentric sleeve 6 is set by rotating it around the inner flange rolling 5 to the position shown in Fig. A-2.

Figure B-2 is a diagram showing a cross section taken along line X-X in Figure A-2. In Figure B-2, the main shaft 7 of the upper roll and the main shaft 7 of the lower roll are brought closer to the position shown in Figure C-2 using the reduction adjustment device. Figure C-2 is a diagram in which the rolled material 12-2 is being edge-rolled using the edge-rolling rolls whose settings have been adjusted. The rolled material 12-2 is the web restraint roll 1
While the web is restrained at 0, the flange end is rolled and forged by the rolling rolls 8.

Figure A-3, Figure B-3, and Figure C-3 are diagrams showing examples in which the setting positions of the flange rolling roll 8, the inner eccentric sleeve 5, and the outer eccentric sleeve 6 are further changed. As explained in Fig. B-2 and Fig. C-2, the rolled material 12- has a different width of the flange.
In No. 3 as well, the flange end is rolled down and forged while restraining the web.

As described above, the present invention adjusts the length shown by L-1 in Figure B-1 to a desired length. Therefore, the present invention can also be applied to rolled materials with different web thicknesses. It can be applied by adjusting the interval between the main shafts 7 of the rolls.

In the present invention, two eccentric sleeves, an inner eccentric sleeve 5 and an outer eccentric sleeve 6, are used, and the reason for this will be explained below.

Figure 3 is a diagram showing the action of the two eccentric sleeves of the present invention, Figures A and B are a comparative example with one eccentric sleeve, and Figures C and D are the present invention with two eccentric sleeves. .

Figure A is a diagram in which one eccentric sleeve 11 is vertically eccentric, and the flange rolling roll 8 rolls down the flange end of the rolled material 12 between PA and QA. At this time, the web restraining roll 10 holds the web of the rolled material.
It is restrained at the RA point. At this time, the RA point is on a line connecting the axes of the upper and lower flange rolling rolls 8.
Therefore, even if there is only one eccentric sleeve, if the eccentric sleeve 11 is set eccentrically up and down, the web restraint point RA is located directly below (directly above) the rolled portions Pa to QA, so the grip of the web will be difficult. Reliable and good etching is ensured.

However, when using this roll to edge roll a rolled material with a narrow flange width, the eccentric sleeve 11 is
It is set horizontally eccentrically as shown in the figure. The flange rolling roll 8 rolls and forges the flange end of the rolled material between PB and QB. Further, the web restraining roll 10 restrains the web of the rolled material at the RB point. but
In this case, the RB point is the upper and lower flange rolling rolls 8
The position is offset by m from the line connecting the axes of . Therefore, in Figure B, the web restraining roll 10 is
The web of the rolled material is restrained at a position offset from the part where the flange is rolled, but in this restrained position, the grip of the rolled material is uncertain, the edging becomes inaccurate, and the threading condition of the rolled material is also unstable. Also, it causes upward and downward warpage in the rolled material.

Since the present invention is equipped with two eccentric sleeves, an inner eccentric sleeve and an outer eccentric sleeve, the position where the web restraining roll 10 restrains the web during the edge rolling is set between the upper and lower flange rolling rolls 8 as shown by RC in Figure C. You can also set it to the position where the axes are connected, or change the settings of 5 and 6 to get the position shown in figure D.
Like RD, it can be restrained at any shifted position. Therefore, in the present invention, even for rolled materials having different flange widths, the web is always restrained at the most appropriate position for the rolling of the flange, thereby ensuring good edging and a smooth path of the rolled material.

Next, the inner eccentric sleeve 5 and the outer eccentric sleeve 6
We will explain the device for setting.

In FIG. 1, 13 is an example of a device for setting the outer eccentric sleeve 6 in a fixed position, for example, an arm 13-1 provided on the frame of a rolling mill, a hydraulic mechanism 13-2 provided at the tip of the arm, and this hydraulic mechanism. This is a setting device consisting of a pressing rod 13-3 that expands and contracts left and right.
The left and right outer eccentric sleeves 6 are rotated to the desired setting position, and the pressing rod 13-3 of the setting device arranged between the left and right outer eccentric sleeves 6 is moved by the hydraulic mechanism 13-.
2, the left and right eccentric sleeves 6 are simultaneously set in that position.

In FIG. 1, reference numeral 14 indicates a device for setting the inner eccentric sleeve 5 in the normal position, and the left and right 5 can be set in the normal position, for example, by the same method as the above-mentioned 13. When this setting device for setting 5 and 6 at regular positions is used, the edge L-1 in FIG. 2 B-1 is always kept constant and the edge rolling is performed.

Next, a sleeve position setting device (hereinafter abbreviated as constant pressure type setting device) equipped with a constant pressure holding mechanism will be explained. In the present invention, the web restraint roll 10 restrains the web of a rolled material, but does not roll down the web. For example, if the gap between the web restraint rolls 10 is narrow relative to the web thickness of the rolled material before biting, or if there is variation in the web thickness of the rolled material before biting, excessive load will be applied to the rolls and stand housing. It sounds. As a result, equipment damage and generation of web waves may occur. Therefore, it is desirable that when an excessive load is applied to the web restraint roll 10, the gap between the upper and lower web restraint rolls automatically increases. For example, if there is a change in the web thickness, L-2 will change in Fig. 2 B-1, so with the eccentric sleeve setting devices 13 and 14 mentioned above, the flange width L-3 after edge rolling will also change. I will do it.

FIG. 4 is a diagram showing an example of a constant pressure type setting device.
13-a is a constant pressure type setting device for the outer eccentric sleeve 6, which is used to set the web restraint roll 1 during the edge rolling.
When a load greater than the preset load Po is applied to 0,
The set position of the outer eccentric sleeve 6 is automatically moved to a position where the load is reduced to Po.

Note that, for example, a hydraulic cylinder or the like can be used as 13-a, and the set load Po is determined by controlling the hydraulic pressure of the hydraulic cylinder.

14-a is a constant pressure type setting device for the inner eccentric sleeve 5, and is constructed in the same manner as 13-a.

Although FIG. 4 shows an example in which 13-a and 14-a operate separately, the positions of eccentric sleeves 5 and 6 can be controlled as a single device using a mechanism such as a lever arm or pinion gear. It may also be a constant pressure type installation device that is set at the same time.

When the positions of the eccentric sleeves 5 and 6 are set using these constant pressure type setting devices, when the thick part of the web of the rolled material passes through the web restraint roll 1
The positions of the eccentric sleeves 5 and 6 are changed so that the load of 0 exceeds the set load Po, and therefore the distance between the upper and lower web restraint rolls 10 automatically increases.
The web is not rolled down excessively, and rolling troubles can be prevented.

Furthermore, using a constant pressure type setting device, set the eccentric sleeves 5 and 6.
Even if the position of the flange rolling roll 8 changes, the position of the flange rolling roll 8 does not change, so the flange width of the rolled material after edging rolling, shown at L-3 in Figure 2 B-1, is always constant, and the flange width accuracy A rolled material with good quality can be obtained.

Although the present invention has been described with respect to an H-section steel, the present invention can also be used as an edging roll for a vertically asymmetric section steel as shown in FIG. 5A. In this case, for example, the lower roll is set as shown in FIG. 2 A-1, and the upper roll is set as shown in FIG. 2 A-3.

Furthermore, by using the roll of the present invention, it is possible to produce a shaped steel whose flange width is gradually changed in the longitudinal direction as shown in Fig. 5B, or a shaped steel whose flange width is changed stepwise as shown in Fig. 5C. The rolling can be carried out by continuously or discontinuously adjusting the positions of the eccentric sleeves 5 and 6 during rolling.

[Operations and Examples] When the edging roll of the present invention is edging a rolled material, the sleeve fitting portion 8b of the flange rolling roll rotates inside the inner eccentric sleeve 5 which is set and held at a predetermined position. move. The web restraint ring 10 also rotates outside the outer eccentric sleeve 6 which is set and held in place. Therefore, the fitting between 5 and 8b and the fitting between 6 and 10 should be such that rotation is easy. For example, if the inner periphery of 5 or the outer periphery of 6 itself is made into a bearing ring or a liner having a bearing function, a compact and smooth fitting can be achieved.

Figure 2 A-1 shows the one-side flange width L- of the rolled material.
This is a case where 5 and 6 are set at the position where 1 is the maximum, and in this case, L1 (max) = (maximum thickness of 5) + (maximum thickness of 6) + (thickness of 10).

Also, L-1 becomes the minimum when it is set as shown in Figure 2 A-3, in which case L1 (Min) = (Minimum thickness of 5) + (Minimum thickness of 6) + (Minimum thickness of 10) thickness).

Therefore, the edging roll of the present invention has L-
1 can be applied to rolled materials in the range of L1 (max) to L1 (min).

Next, the scene shown in FIG. 2 A-2 will also be explained. In FIG. 6, O is the center of the flange rolling roll 8, Oa is the center of the outer circumference of the outer eccentric sleeve 6, and Ob is the center of the outer circumference of the inner eccentric sleeve 5. As already mentioned, it is desirable that the position where the web restraint ring 10 restrains the web be near the line connecting the axes of 8, that is, the O--O line. Therefore, Oa is near the O-O line, for example on the O-O line. A case where the Ob point is displaced by θ degrees will be explained. In this case, it is expressed as E(θ)=Eb cosθ±√ ² −( ) ² . Here, Ea is the eccentricity of 6 with respect to 5, and Eb is the eccentricity of 5 with respect to 8, and these are determined by the shapes of 8, 5, and 6.

Letting Emax be the gap between O and Oa at L1 (max), Emax=Ea+Eb.

Further, when the Ob point is displaced by θ degrees, the gap between O and Oa is E(θ) as described above.

Therefore, when the Ob point is displaced by θ degrees, L-1, that is,
L1 (θ) is expressed as L1 (θ) = L1 (max) - [Emax - E (θ)] and is expressed as a function of the angle θ. Therefore, L-1 corresponding to the flange width on one side of the rolled material is θ can be set as desired by adjusting.

Next, the constant pressure type setting device of the present invention has a structure (hereinafter abbreviated as self-release structure) in which the interval between the upper and lower web restraint rolls 10 automatically increases when an overload of a predetermined value or more is applied to the web restraint roll 10.
It is.

The conditions for this self-release are shown below.
Figure 7 shows the axis of the web restraint roll (same as the axis of the outer eccentric sleeve) Oa-Oa and the axis of the main shaft O-
The arrangement of the edger rolls and the symbols of each part are shown when O is arranged on the same line.Here, for simplicity, the load P acting on the web restraint roll is set to the axis Oa−.
It is considered to act intensively on Oa. Fig. 7A shows the overall positional relationship of the etching rolls, and B
1 illustrates the relationship between the forces acting on the upper roll side.

If the angle between the tangent at the Oa-Oa position, which is the point of action of the load P, on the boundary between the inner and outer eccentric sleeves and the rolling direction is θ', then the external force P acting on the outer sleeve is can be decomposed into a tangential force Psinθ' and a normal force Pcosθ' perpendicular to the inner and outer eccentric sleeve boundaries. Therefore, if the friction coefficient between the inner and outer eccentric sleeves is μ, the frictional force acting on the interface is μPcosθ'.

When load P is applied, the condition for the relative position between the eccentric sleeves to self-release instead of self-locking is given by Psinθ′>μPcosθ′, so tanθ′>μ (self-release conditional formula) From the inner eccentric sleeve A similar self-release conditional expression can also be obtained.

Here, if the bearing of the eccentric sleeve is a general rolling bearing, μ≈0.003, so θ′>0.17°. In other words, when θ′ exceeds 0.17°, when a load is applied to the web restraint roll, the two eccentric sleeves do not self-lock and can automatically move toward each other in the direction of increasing the roll gap of the web restraint roll. means. Therefore, within a practical range, the structure can be selected to satisfactorily satisfy this self-release condition.

By the way, generally speaking, the side wall of an etching roll has an inclination of .gamma. as shown in FIG. 8 due to its shape. Therefore, if the roll is constructed based on FIG. 8A, where the flange width L is the minimum, in FIG. gives rise to ε.
If the edging rolling is performed in this state, the flange end portion 12a will not be properly restrained by the flange etching hole portion 8a.In particular, the larger γ is in the side wall inclination and the larger the shared range of the flange width L, the more stable the flange will be. This makes it impossible to maintain a good aging condition.

In the present invention, as shown in FIG. 8C, by using a trapezoidal screw 60 having a lead angle commensurate with the abutment circumferential circle of both eccentric sleeves 5 and 6 and the eccentric angle θ, it automatically comes into contact with the rolled material 12. Since the outer surfaces of the contacting roll elements are aligned on the same line, stable and good edging rolling can be performed.

Note that Fig. 8 is a specific example when applied to the eccentric sleeve fixed position holding method, but when applied to the self-release structure as shown in Fig. 4, the threaded part should be a ball screw etc. It is only necessary to minimize the turning resistance.

[Effect of the invention] According to the present invention, it is always possible to roll the flange ends of rolled materials of various shapes with different flange widths and web thicknesses while restraining the web using the same edging roll. Become.

In the present invention, since L-1 in Fig. 2 B-1 can be adjusted to the desired length, the accuracy of the L-1 dimension of the rolled material is good, and the flange end is stably and sufficiently forged, resulting in excellent quality. , and there is no web-off-center in the rolled material, and the flanges of the rolled material are less likely to collapse or bend during edge rolling.

Since the web restraint roll 10 of the present invention is rotatable and does not hinder the running of the web portion in the rolling direction, the roll circumferential speed of the flange contact portion and the web contact portion, which occurs in the conventional integrated edging roll, is reduced. Problems caused by differences, such as uneven wear of the rolls, surface flaws on the rolled material, and warping of the rolled material, can be significantly improved. In the present invention, the restraining position of the web of the rolled material can be set at the optimal position for rolling down the flanges near the line connecting the axes of the upper and lower flange rolling rolls 8, resulting in good edging and smooth rolling. A path for materials can be secured.

Further, when the constant pressure mold setting device of the present invention is used, the web of the rolled material is not rolled down excessively, troubles in the rolling operation can be prevented, and the flange width L-3 of the rolled material is always accurate.

[Brief explanation of drawings]

FIG. 1 is a diagram showing an example of the edging roll of the present invention, and FIG. 2 is a diagram showing an example in which the setting positions are changed by rotating the flange rolling roll 8, inner eccentric ring 5, and outer eccentric ring 6. , FIG. 3 is a diagram showing the action of the two eccentric sleeves of the present invention, FIG. 4 is a diagram showing an example of the constant pressure type setting device of the present invention, and FIG.
The figures are diagrams showing examples of objects to which the present invention is applied other than H-section steel, Figure 6 is a diagram explaining the action of the present invention, and Figure 7 is a diagram illustrating the effects of the present invention.
The figure is an overall configuration diagram of a self-release type edging roll of the constant pressure type setting device of the present invention, and FIG. 8 is the minimum width of one side of the roll flange in FIG.
An explanatory diagram showing the relative positional relationship between the horizontal roll, the eccentric sleeve, and the web restraint roll at the maximum opening degree,
FIG. 9 is a diagram showing an example of the universal rolling method, and FIG. 10 is a diagram showing an example of inconvenient problems that occur in the conventional edging rolling method. 1: Breakdown mill, 2 (2a, 2b):
Universal rolling mill, 3 (3a): Edging rolling mill, 4 (4a, 4b): Finishing universal rolling mill, 5: Inner eccentric sleeve, 6: Outer eccentric sleeve, 7: Main shaft, 8 (8a, 8b): Flange rolling roll, 9: key, 10: web restraint roll,
11: Eccentric sleeve of comparative example, 12 (12a):
Rolled material, 13 (13a): outer eccentric sleeve positioning device, 14 (14a): inner eccentric sleeve positioning device.

Claims (1)

[Claims] 1. A flange rolling roll 8 having a flange rolling part 8a and a sleeve fitting part 8b on the left and right sides of the main shaft 7.
is provided so as to rotate with the main shaft 7, and the inner eccentric sleeve 5 is provided on the outside of the sleeve fitting part 8b so that it can be set by rotating on the outer circumference of the sleeve fitting part 8b. An outer eccentric sleeve 6 is provided so as to be rotatable on the outer circumference of the inner eccentric sleeve 5, and a web restraint roll 10 is provided on the outer side of the outer eccentric sleeve 6 so as to be rotatable on the outer circumference of the outer eccentric sleeve 6. An edging roll for a profile with flanges, characterized by: 2 A patent in which the rolling roll 8 provided to rotate together with the main shaft 7 is a rolling roll 8 provided to rotate together with the main shaft 7 and to be settable by sliding on the main shaft 7 in the axial direction. An edging roll for a profile having a flange according to claim 1. 3 Insert the inner eccentric sleeve 5 into the sleeve fitting part 8b
The inner sleeve position setting device 14 sets the outer circumferential eccentric sleeve 6 by rotating it on the outer periphery of the inner sleeve 5, and the outer sleeve position setting device 13 sets the outer circumferential eccentric sleeve 6 by rotating it on the outer periphery of the inner eccentric sleeve 5. An edging roll for a profile with flanges according to claim 1 or 2, which is a sleeve positioning device.